US 20140050836A1 (19) United States (12) Patent Application Publication (10) Pub. No.: US 2014/0050836 A1 COX et al. (43) Pub. Date: Feb. 20, 2014 (54) STABILIZED AERATED FROZEN (22) Filed: Aug. 14, 2012 CONFECTION CONTAINING HYDROPHOBIN Publication Classi?cation (75) Inventors: ANDREW RICHARD COX, (51) Int- Cl SHARNBROOK (GB); NICHOLAS A236 9/20 (2006-01) DAVID HEDGEs, SHARNBROOK A23G 9/38 (2006-01) (GB); DAMIANO ROssETTI, (52) U-S- Cl SHARNBROQK (GB); JAKOB USPC ........................................................ .. 426/565 BROBERG KRIsTENsEN, LANGA (DK) (57) ABSTRACT A frozen aerated confection is disclosed that is stable to (73) Assigneer CONOPCO, INC-1 D/B/A UNILEVER, temperature abuse. A synergistic stabilization effect regard EnglBWOOd Cliffs, NJ (US) ing the combination of hydrophobin, a Secondary protein and a Co-surfactant is described that results in the observed sta (21) Appl. No.: 13/585,257 biliZation. Patent Application Publication Feb. 20, 2014 Sheet 1 0f 7 US 2014/0050836 A1 gmmmmmw iWimvvvvvvvvvvvvvvvvvvzvvvvvvvvvvvvvvvvvvv.vvvvvvvvvvvvvvvvv ;, »i 71J.;Q.i. ».k ?;. wwawiommm§wmxmmmdnzmm+Hmud? aJJhHaJI? m ?MIa i? ?Q>ro>oNwmPwZm+ia vWEDQE aQ11 mQmnvQmnv 2we; naiamnPvw gm wwWrHMyao v;nDsii‘iiii i : ., , a5aw.4, mm QQQmwcaomoooowwavw”mmmm”, ia4vH» WE3a : Patent Application Publication Feb. 20, 2014 Sheet 2 0f 7 US 2014/0050836 Al wNmmmzm Patent Application Publication Feb. 20, 2014 Sheet 3 0f 7 US 2014/0050836 A1 Patent Application Publication Feb. 20, 2014 Sheet 4 0f 7 US 2014/0050836 A1 wmmmwi .,W Patent Application Publication Feb. 20, 2014 Sheet 5 0f 7 US 2014/0050836 A1 mg 00m om a omm?QwmQmQmm .1 -a-- Eme; npmIa~m~gInu ,éxizii?; nmeowm”” _Q %@ mam Q l CD in P twmwi smnmw angina Patent Application Publication Feb. 20, 2014 Sheet 6 0f 7 US 2014/0050836 A1 mom EO mi g5.W3 %.m» i _.._u._ Emg; 00oooo0ms00osoomo9a2mwmwmm%w“wmmm»“ [DJ/Nu} snmpow nusegg Patent Application Publication Feb. 20, 2014 Sheet 7 0f 7 US 2014/0050836 A1 E35% hwmmmzm US 2014/0050836 A1 Feb. 20, 2014 STABILIZED AERATED FROZEN b. Adding hydrophobin and a Co-surfactant or Co-surfactants CONFECTION CONTAINING to the chilled mix of step (a); HYDROPHOBIN c. Aerating and freeZing the mix of step (b) to produce the aerated and froZen product; and BACKGROUND OF THE INVENTION d. Cooling the froZen product to a storage temperature of less than about —15 C. [0001] 1. Field of the Invention [0002] The present invention relates to the production of an BRIEF DESCRIPTION OF THE DRAWINGS aerated froZen confectionery comprising of hydrophobin, a Secondary protein, and a Co-surfactant (CSF). [0012] FIG. 1 is a graphical representation of Elastic modu [0003] 2. Background ofthe Art lus for Example 1, samples A) HFBII, (B) HFBII+SMP and [0004] It is desirable to make small siZe bubbles in aerated (C) HFBII+SMP+CSF (TWN20) at 5° C. as a function of froZen confections that are stable to temperature abuse in time. order to improve texture, palatability, and reduce caloric con [0013] FIG. 2 depicts SEM images for Example 1, HFBII tent. It is Well understood that froZen confections such as (a, d), HFBII+SMP (b, e) and HFBII+SMP+CSF (TWN20) sorbets, sherbets and ice cream experience temperature ?uc (c, f) for ice cream formulations described in Table 2. Images tuations in the distribution chain and in consumers’ home shoW fresh samples (a to c) and after the storage test (d to f), freeZers. This results in bubble growth and a degradation of Which includes the standard temperature abuse protocol. the product quality and the palatability on consumption. It is [0014] FIG. 3 depicts SEM images of comparative samples preferable to produce an ice cream With stable bubbles. containing 0.02 Wt. % TWeen 60 (a, d), 0.02 Wt. % Erythritol [0005] US Patent publication no. 2006024417A, published (b, e), and 0.03 Wt. % Hygel (c, f). All samples include HFBII on Feb. 2, 2006 to Berry et al. discloses aerated products (0.2 Wt. %) SMP (8.22 Wt. %)+comparative surfactant at comprising hydrophobin Where the hydrophobin is used to concentration indicated. Images shoW fresh samples (a to c) inhibit bubble coarsening. and after the storage test (d to f), Which includes the standard [0006] US Patent publication no. 2008213453A published temperature abuse protocol. Samples correspond to equiva on Sep. 4, 2008 to Burmester et al. discloses aerated food lent model formulations described in Table 3. products and methods producing them, Where in the product [0015] FIG. 4 depicts SEM images of inventive samples comprises hydrophobin and a surfactant. containing 0.02 Wt. TWeen 20 (a, d), 0.06 Wt. % TWeen 60 (b, [0007] We have unexpectedly found that When the combi e), and 0.02 Wt. % PGE-O-80 (c, f). All samples include nation of hydrophobin, at least one Secondary protein and at HFBII (0.2 Wt. %)+SMP (8.22 Wt. %)+inventive surfactant at least one Co-surfactant (as those terms are de?ned beloW) are concentration indicated. Images shoW fresh samples (a to c) used to make an aerated froZen confectionery product then: and after the storage test (d to f), Which includes the standard [0008] The microstructure of the freshly produced prod temperature abuse protocol. Samples correspond to equiva uct is preferable since the air bubbles siZes are generally lent model formulations described in Table 3. smaller augmenting the bene?cial qualities described [0016] FIG. 5: is a graphical representation of Elastic above. modulus for HFBI class II, HFBI class II+SMP and HFBI [0009] The microstructure of the product after storage class II+SMP+CSF (TWN20) at 5° C. for indicated concen and temperature abuse is preferable since the air bubbles trations as a function of time. siZes are more stable and do not groW (coarsen) to the [0017] FIG. 6: is a graphical representation of Elastic same extent as comparative cases. modulus for CU class II, CU class II+SMP and CU class II+SMP+CSF (TWN20) at 5° C. for indicated concentrations BRIEF DESCRIPTION OF THE INVENTION as a function of time. [0018] FIG. 7 shoWs a schematic depiction of a micrograph [0010] In one aspect of the invention is a froZen aerated illustrating the guard frame concept for bubble siZe measure food composition including but not limited to ment. a. at least 0.01 Wt. % of total hydrophobin(s) selected from the group consisting of HFBII, HFBI or Cerato Ulmin or blends DETAILED DESCRIPTION OF THE INVENTION thereof added in isolated form to the food composition; b, one or more Co-surfactants in the total concentration range [0019] In one aspect of the invention is a froZen aerated of about 0.001 to less than about 0.3 Wt. % (preferably less food composition including but not limited to: than about 0.1 or 0.2 Wt. %), and the Co-surfactant(s) to total a. at least 0.01 Wt. % of total hydrophobin(s) selected from the hydrophobin Wt, ratio is in the range of about 0.02 to less than group consisting of HFBII, HFBI or Cerato Ulmin or blends 1.0. (Preferably the Co-surfactant to hydrophobin Wt. ratio is thereof added in isolated form to the food composition; at least about 0.05, more preferably at least about 0.3 and b. one or more Co-surfactants in the total concentration range preferably at most about 0.75); and of about 0.001 to less than about 0.3 Wt. % (preferably less c. one or more Secondary protein(s) that are different from than about 0.1 or 0.2 Wt. %), and the Co-surfactant(s) to total hydrophobin(s): Wherein said Secondary protein(s) are hydrophobin Wt. ratio is in the range of about 0.02 to less than present in a total concentration range of about 0.25 to less than 1.0. (Preferably the Co-surfactant to hydrophobin Wt. ratio is 6.0 Wt. % (Preferably the total Secondary protein(s) are at at least about 0.05, more preferably at least about 0.3 and least 0.5 or 1.0 Wt. % and at most 4 or 5 Wt. %). preferably at most about 0.75); and [0011] In another aspect of the invention is a process of c. one or more Secondary protein(s) that are different from making an aerated food composition including but not limited hydrophobin(s) Wherein said Secondary protein(s) are to the steps of: present in a total concentration range of about 0.25 to less than a. Blending the food composition ingredients together, mix 6.0 Wt. % (Preferably the total Secondary protein(s) are at ing, and pasteurising; least 0.5 or 1.0 Wt. % and at most 4 or 5 Wt. %). US 2014/0050836 A1 Feb. 20, 2014 [0020] Advantageously the total hydrophobin(s) concen The stability of the aeration can be assessed by monitoring the tration is at most 1.5 Wt. %. Preferably the Co-surfactants is or volume of the aerated product over time and or the bubble size are Water soluble non-ionic surfactant(s). More preferably the change over time. Co-surfactant(s) are selected from Polysorbates, polyglyc erol esters of alkyl or alkenyl fatty acids, diacetyl tartartic acid Microstructure esters of mono-/di-glycerides, sucrose esters With an HLB >about 8 orblends thereof. Most preferably the Co-surfactant [0028] The microstructure of frozen confections is critical (s) has a minimum effective HLB value of about 8. Effective to their organoleptic properties. The air cells incorporated HLB value is here de?ned as the arithmetic mean of the HLB into frozen confections are preferably small in size Which values of a blend of Co-surfactants Advantageously the Co ensures that the frozen confections do not have a coarse surfactant(s) is selected from TWeens 20, 60 or 80, PGE-O texture and also ensures that they deliver a smooth creamy 80; Panodan-Visco Lo 2000 and blends thereof. mouth-feel. In typical ice cream products, the air bubbles coarsen over time (through distribution and storage) leading [0021] Preferably the average bubble diameter (d3,2) is at least 10% smaller after the standard temperature abuse pro to a degradation in quality. tocol described beloW than the same product prepared the Hydrophobins same Way but absent either hydrophobin(s), Co-surfactant(s) or if both are present then outside the total Co-surfactant(s) to [0029] Hydrophobins are a Well-de?ned class of proteins hydrophobin(s) ratio range of about 0.02 to less than 1.0. (Wessels, 1997, Adv. Microb. Physio. 38: 1-45; Wosten, Preferably the average bubble size is at least 20, 30, 40 or 50% 2001, Annu Rev. Microbiol. 55: 625-646) capable of self smaller. assembly at a hydrophobic/hydrophilic interface, and having [0022] Preferably the average bubble diameter d(3,2) of the a conserved sequence: freshly prepared frozen product stored at beloW about — 1 5 ° C. and pre-temperature abuse is at least 10% smaller, preferably 15% smaller, and more preferably 20% smaller than the same product prepared the same Way but absent either hydrophobin (s). Co-surfactant(s) or if both are present then outside the total Co-surfactant(s) to hydrophobin(s) ratio range of about Where X represents any amino acid, and n and m indepen 0.02 to less than 1.0. dently represent an integer. Typically, a hydrophobin has a [0023] In another aspect of the invention is a process of length of up to 125 amino acids. The cysteine residues (C) in making an aerated food composition including but not limited the conserved sequence are part of disulphide bridges. In the to the steps of: context of the present invention, the term hydrophobin has a Wider meaning to include functionally equivalent proteins a. Blending the food composition ingredients together mix still displaying the characteristic of self-assembly at a hydro ing, and pasteurising; phobic-hydrophilic interface resulting in a protein ?lm, such b. Adding hydrophobin and a Co-surfactant or Co-surfactants as proteins comprising the sequence: to the chilled mix of step (a); c. Aerating and freezing the mix of step (b) to produce the aerated and frozen product; and d. Cooling the frozen product to a storage temperature of less than about —15 C. [0024] Preferably the process further includes the step of extruding the frozen product from a freezer at a temperature or parts thereof still displaying the characteristic of self of about —5 C or less. assembly at a hydrophobic-hydrophilic interface resulting in [0025] All percentages, unless otherWise stated, refer to the a protein ?lm. In accordance With the de?nition of the present percentage by Weight, With the exception of percentages cited invention, self-assembly can be detected by adsorbing the in relation to the overrun. protein to Te?on and using Circular Dichroism to establish the presence of a secondary structure (in general, ot-helix) (De Frozen Confections Vocht et al., 1998, Biophys. 1.74:2059-68). [0030] The formation of a ?lm can be established by incu [0026] The term “frozen confection” means an edible con bating a Te?on sheet in the protein solution folloWed by at fection made by freezing a mix of ingredients Which includes least three Washes With Water or buffer Masten et al., 1994, Water. Frozen confections typically contain fat, non-fat milk Embo. J. 13: 5848-54). The protein ?lm can be visualised by solids and sugars, together With other minor ingredients such any suitable method, such as labeling With a ?uorescent as stabilisers, emulsi?ers, colours and ?avourings. Frozen marker or by the use of ?uorescent antibodies, as is Well confections include ice cream, Water ice, frozen yoghurt, established in the art. In and n typically have values ranging sherbets, sorbet and the like. from 0 to 2000, but more usually m+n<100 or 200. The de?nition of hydrophobin in the context of the present inven Aeration tion includes fusion proteins of a hydrophobin and another [0027] The term aeration means that gas has been incorpo polypeptide as Well as conjugates of hydrophobin and other rated into a product to form air cells. The gas can be any gas molecules such as polysaccharides. but is preferably, particularly in the context of food products, [0031] Hydrophobins identi?ed to date are generally a food-grade gas such as air, nitrogen or carbon dioxide or a classed as either class I or class II Both types have been mixture of the aforementioned. The extent of the aeration can identi?ed in fungi as secreted proteins that self-assemble at be measured in terms of the volume of the aerated product. hydrophobilic interfaces into amphipathic ?lms. Assem